ref: 994751d39485e086ef623f202fb1b84729fd5d19
dir: /src/cmd/cc/cc1/expr.c/
#include <assert.h>
#include <stdlib.h>
#include <string.h>
#include <scc/cstd.h>
#include <scc/scc.h>
#include "cc1.h"
#define XCHG(lp, rp, np) (np = lp, lp = rp, rp = np)
static Node *xexpr(void), *xassign(void);
int
cmpnode(Node *np, TUINT val)
{
Symbol *sym;
Type *tp;
TUINT mask, nodeval;
if (!np || !(np->flags & NCONST) || !np->sym)
return 0;
sym = np->sym;
tp = sym->type;
switch (tp->op) {
case PTR:
case INT:
mask = (val > 1) ? ones(np->type->size) : -1;
nodeval = (tp->prop & TSIGNED) ? sym->u.i : sym->u.u;
return (nodeval & mask) == (val & mask);
case FLOAT:
return sym->u.f == val;
}
return 0;
}
static Node *
promote(Node *np)
{
Type *tp;
Node *new;
struct limits *lim, *ilim;
tp = np->type;
switch (tp->op) {
case ENUM:
case INT:
if (tp->n.rank >= inttype->n.rank)
return np;
lim = getlimits(tp);
ilim = getlimits(inttype);
tp = (lim->max.i <= ilim->max.i) ? inttype : uinttype;
break;
case FLOAT:
/* TODO: Add support for C99 float math */
tp = doubletype;
break;
default:
abort();
}
if ((new = convert(np, tp, 1)) != NULL)
return new;
return np;
}
static void
arithconv(Node **p1, Node **p2)
{
int to = 0, s1, s2;
unsigned r1, r2;
Type *tp1, *tp2;
Node *np1, *np2;
struct limits *lp1, *lp2;
np1 = promote(*p1);
np2 = promote(*p2);
tp1 = np1->type;
tp2 = np2->type;
if (tp1 == tp2)
goto set_p1_p2;
s1 = (tp1->prop & TSIGNED) != 0;
r1 = tp1->n.rank;
lp1 = getlimits(tp1);
s2 = (tp2->prop & TSIGNED) != 0;
r2 = tp2->n.rank;
lp2 = getlimits(tp2);
if (s1 == s2 || tp1->op == FLOAT || tp2->op == FLOAT) {
to = r1 - r2;
} else if (!s1) {
if (r1 >= r2 || lp1->max.i >= lp2->max.i)
to = 1;
else
to = -1;
} else {
if (r2 >= r1 || lp2->max.i >= lp1->max.i)
to = -1;
else
to = 1;
}
if (to > 0)
np2 = convert(np2, tp1, 1);
else if (to < 0)
np1 = convert(np1, tp2, 1);
set_p1_p2:
*p1 = np1;
*p2 = np2;
}
static int
null(Node *np)
{
if (np->type != pvoidtype || np->op != OCAST)
return 0;
np = np->left;
if (np->type != inttype)
return 0;
return cmpnode(np, 0);
}
static Node *
chkternary(Node *yes, Node *no)
{
/*
* FIXME:
* We are ignoring type qualifiers here,
* but the standard has strong rules about this.
* take a look to 6.5.15
*/
if (!eqtype(yes->type, no->type, 1)) {
if ((yes->type->prop & TARITH) && (no->type->prop & TARITH)) {
arithconv(&yes, &no);
} else if (yes->type->op != PTR && no->type->op != PTR) {
goto wrong_type;
} else {
/* convert integer 0 to NULL */
if ((yes->type->prop & TINTEGER) && cmpnode(yes, 0))
yes = convert(yes, pvoidtype, 0);
if ((no->type->prop & TINTEGER) && cmpnode(no, 0))
no = convert(no, pvoidtype, 0);
/*
* At this point the type of both should be
* a pointer to something, or we have don't
* compatible types
*/
if (yes->type->op != PTR || no->type->op != PTR)
goto wrong_type;
/*
* If we have a null pointer constant then
* convert to the another type
*/
if (null(yes))
yes = convert(yes, no->type, 0);
if (null(no))
no = convert(no, yes->type, 0);
if (!eqtype(yes->type, no->type, 1))
goto wrong_type;
}
}
return node(OCOLON, yes->type, yes, no);
wrong_type:
errorp("type mismatch in conditional expression");
freetree(yes);
freetree(no);
return constnode(zero);
}
static void
chklvalue(Node *np)
{
if (!(np->flags & NLVAL))
errorp("lvalue required in operation");
if (np->type == voidtype)
errorp("invalid use of void expression");
}
Node *
decay(Node *np)
{
Node *new;
Type *tp = np->type;
switch (tp->op) {
case ARY:
tp = tp->type;
if (np->op == OPTR) {
new = np->left;
free(np);
new->type = mktype(tp, PTR, 0, NULL);
return new;
}
case FTN:
new = node(OADDR, mktype(tp, PTR, 0, NULL), np, NULL);
if (np->sym && np->sym->flags & (SGLOBAL|SLOCAL|SPRIVATE))
new->flags |= NCONST;
return new;
default:
return np;
}
}
static Node *
integerop(int op, Node *lp, Node *rp)
{
if (!(lp->type->prop & TINTEGER) || !(rp->type->prop & TINTEGER))
error("operator requires integer operands");
arithconv(&lp, &rp);
return node(op, lp->type, lp, rp);
}
static Node *
integeruop(int op, Node *np)
{
if (!(np->type->prop & TINTEGER))
error("unary operator requires integer operand");
np = promote(np);
return node(op, np->type, np, NULL);
}
static Node *
numericaluop(int op, Node *np)
{
if (!(np->type->prop & TARITH))
error("unary operator requires numerical operand");
np = promote(np);
return node(op, np->type, np, NULL);
}
Node *
convert(Node *np, Type *newtp, int iscast)
{
Type *oldtp = np->type;
int op = newtp->op;
if (eqtype(newtp, oldtp, 0))
return np;
if (iscast && op == VOID)
goto good_conv;
switch (oldtp->op) {
case ENUM:
case INT:
if (op == PTR && (iscast || cmpnode(np, 0)))
goto good_conv;
case FLOAT:
if (op == INT || op == FLOAT || op == ENUM)
goto good_conv;
return NULL;
case PTR:
if (op == ENUM || op == INT) {
if (iscast)
goto good_conv;
} else if (op == PTR) {
if (eqtype(newtp, oldtp, 1))
goto good_conv;
if (iscast)
goto good_conv;
if (newtp == pvoidtype || oldtp == pvoidtype)
goto good_conv;
}
default:
return NULL;
}
good_conv:
return node(OCAST, newtp, np, NULL);
}
static Node *
parithmetic(int op, Node *lp, Node *rp)
{
Type *tp;
Node *size, *np;
if (lp->type->op != PTR)
XCHG(lp, rp, np);
tp = rp->type;
if (tp->op == PTR && !(tp->type->prop & TDEFINED))
goto incomplete;
tp = lp->type;
if (!(tp->type->prop & TDEFINED))
goto incomplete;
size = sizeofnode(tp->type);
if (op == OSUB && BTYPE(rp) == PTR) {
if ((rp = convert(rp, lp->type, 0)) == NULL)
goto incorrect;
lp = node(OSUB, pdifftype, lp, rp);
return node(ODIV, inttype, lp, size);
}
if (!(rp->type->prop & TINTEGER))
goto incorrect;
rp = convert(promote(rp), sizettype, 0);
rp = node(OMUL, sizettype, rp, size);
rp = convert(rp, tp, 1);
return node(op, tp, lp, rp);
incomplete:
errorp("invalid use of undefined type");
return lp;
incorrect:
errorp("incorrect arithmetic operands");
return lp;
}
static Node *
arithmetic(int op, Node *lp, Node *rp)
{
Type *ltp = lp->type, *rtp = rp->type;
if ((ltp->prop & TARITH) && (rtp->prop & TARITH)) {
arithconv(&lp, &rp);
return node(op, lp->type, lp, rp);
} else if ((ltp->op == PTR || rtp->op == PTR)) {
switch (op) {
case OADD:
case OSUB:
case OA_ADD:
case OA_SUB:
case OINC:
case ODEC:
return parithmetic(op, lp, rp);
}
}
errorp("incorrect arithmetic operands");
return lp;
}
static Node *
pcompare(int op, Node *lp, Node *rp)
{
Node *np;
if (lp->type->prop&TINTEGER) {
if ((np = convert(lp, rp->type, 0)) == NULL)
errorp("incompatible types in comparison");
else
lp = np;
}
if (rp->type->prop&TINTEGER) {
if ((np = convert(rp, lp->type, 0)) == NULL)
errorp("incompatible types in comparison");
else
rp = np;
}
return convert(node(op, pvoidtype, lp, rp), inttype, 1);
}
static Node *
compare(int op, Node *lp, Node *rp)
{
Type *ltp, *rtp;
ltp = lp->type;
rtp = rp->type;
if (ltp->op == PTR || rtp->op == PTR) {
return pcompare(op, lp, rp);
} else if ((ltp->prop & TARITH) && (rtp->prop & TARITH)) {
arithconv(&lp, &rp);
return convert(node(op, lp->type, lp, rp), inttype, 1);
} else {
errorp("incompatible types in comparison");
freetree(lp);
freetree(rp);
return constnode(zero);
}
}
int
negop(int op)
{
switch (op) {
case OEQ: return ONE;
case ONE: return OEQ;
case OLT: return OGE;
case OGE: return OLT;
case OLE: return OGT;
case OGT: return OLE;
default: abort();
}
return op;
}
static Node *
exp2cond(Node *np, int neg)
{
int op;
if (np->type->prop & TAGGREG) {
errorp("used struct/union type value where scalar is required");
return constnode(zero);
}
switch (np->op) {
case ONEG:
case OOR:
case OAND:
return (neg) ? node(ONEG, inttype, np, NULL) : np;
case OEQ:
case ONE:
case OLT:
case OGE:
case OLE:
case OGT:
if (neg)
np->op = negop(np->op);
return np;
default:
op = (neg) ? OEQ : ONE;
return compare(op, np, constnode(zero));
}
}
static Node *
logic(int op, Node *lp, Node *rp)
{
lp = exp2cond(lp, 0);
rp = exp2cond(rp, 0);
return node(op, inttype, lp, rp);
}
static Node *
field(Node *np)
{
Symbol *sym;
namespace = np->type->ns;
next();
namespace = NS_IDEN;
sym = yylval.sym;
if (yytoken != IDEN)
unexpected();
next();
if (!(np->type->prop & TAGGREG)) {
errorp("request for member '%s' in something not a structure or union",
yylval.sym->name);
goto free_np;
}
if ((sym->flags & SDECLARED) == 0) {
errorp("incorrect field in struct/union");
goto free_np;
}
np = node(OFIELD, sym->type, np, varnode(sym));
np->flags |= NLVAL;
return np;
free_np:
freetree(np);
return constnode(zero);
}
static Node *
content(int op, Node *np)
{
if (BTYPE(np) != PTR) {
errorp("invalid argument of memory indirection");
} else {
np = node(op, np->type->type, np, NULL);
np->flags |= NLVAL;
}
return np;
}
static Node *
array(Node *lp, Node *rp)
{
Type *tp;
Node *np;
if (!(lp->type->prop & TINTEGER) && !(rp->type->prop & TINTEGER))
error("array subscript is not an integer");
np = arithmetic(OADD, lp, rp);
tp = np->type;
if (tp->op != PTR)
errorp("subscripted value is neither array nor pointer");
return content(OPTR, np);
}
static Node *
assignop(int op, Node *lp, Node *rp)
{
if ((rp = convert(rp, lp->type, 0)) == NULL) {
errorp("incompatible types when assigning");
return lp;
}
return node(op, lp->type, lp, rp);
}
static Node *
incdec(Node *np, int op)
{
Type *tp = np->type;
Node *inc;
chklvalue(np);
np->flags |= NEFFECT;
if (!(tp->prop & TDEFINED)) {
errorp("invalid use of undefined type");
return np;
} else if (tp->op == PTR && !(tp->type->prop & TDEFINED)) {
errorp("%s of pointer to an incomplete type",
(op == OINC || op == OA_ADD) ? "increment" : "decrement");
return np;
} else if (tp->op == PTR || (tp->prop & TARITH)) {
inc = constnode(one);
} else {
errorp("wrong type argument to increment or decrement");
return np;
}
return arithmetic(op, np, inc);
}
static Node *
address(int op, Node *np)
{
Node *new;
/*
* ansi c accepts & applied to a function name, and it generates
* a function pointer
*/
if (np->op == OSYM) {
if (np->type->op == FTN)
return decay(np);
if (np->type->op == ARY)
goto dont_check_lvalue;
}
chklvalue(np);
dont_check_lvalue:
if (np->sym && (np->sym->flags & SREGISTER))
errorp("address of register variable '%s' requested", yytext);
new = node(op, mktype(np->type, PTR, 0, NULL), np, NULL);
if (np->sym && np->sym->flags & (SGLOBAL|SLOCAL|SPRIVATE))
new->flags |= NCONST;
return new;
}
static Node *
negation(int op, Node *np)
{
if (!(np->type->prop & TARITH) && np->type->op != PTR) {
errorp("invalid argument of unary '!'");
return constnode(zero);
}
return exp2cond(np, 1);
}
static Symbol *
adjstrings(Symbol *sym)
{
char *s, *t;
size_t len, n;
Type *tp;
tp = sym->type;
s = sym->u.s;
for (len = strlen(s);; len += n) {
next();
if (yytoken != STRING)
break;
t = yylval.sym->u.s;
n = strlen(t);
s = xrealloc(s, len + n + 1);
memcpy(s+len, t, n);
s[len + n] = '\0';
}
++len;
if (tp->n.elem != len) {
sym->type = mktype(chartype, ARY, len, NULL);
sym->u.s = s;
}
return sym;
}
/*************************************************************
* grammar functions *
*************************************************************/
static Node *
primary(void)
{
Node *np;
Symbol *sym;
Node *(*fun)(Symbol *);
sym = yylval.sym;
switch (yytoken) {
case STRING:
np = constnode(adjstrings(sym));
sym->flags |= SHASINIT;
emit(ODECL, sym);
emit(OINIT, np);
return varnode(sym);
case BUILTIN:
fun = sym->u.fun;
next();
expect('(');
np = (*fun)(sym);
expect(')');
/* do not call to next */
return np;
case CONSTANT:
np = constnode(sym);
break;
case DEFINED:
np = defined();
break;
case IDEN:
assert((sym->flags & SCONSTANT) == 0);
if ((sym->flags & SDECLARED) != 0) {
sym->flags |= SUSED;
np = varnode(sym);
} else if (namespace == NS_CPP) {
np = constnode(zero);
} else {
errorp("'%s' undeclared", yytext);
sym->type = inttype;
sym = install(sym->ns, yylval.sym);
sym->flags |= SUSED;
np = varnode(sym);
}
break;
default:
unexpected();
}
next();
return np;
}
static Node *
arguments(Node *np)
{
int toomany, n, op;
Node *par = NULL, *arg;
Type *argtype, **targs, *tp = np->type, *rettype;
if (tp->op == PTR && tp->type->op == FTN) {
np = content(OPTR, np);
tp = np->type;
}
if (tp->op != FTN) {
targs = (Type *[]) {ellipsistype};
n = 1;
rettype = inttype;
errorp("function or function pointer expected");
} else {
targs = tp->p.pars;
n = tp->n.elem;
rettype = tp->type;
}
expect('(');
if (yytoken == ')')
goto no_pars;
toomany = 0;
do {
arg = xassign();
argtype = *targs;
if (argtype == ellipsistype) {
n = 0;
switch (arg->type->op) {
case INT:
arg = promote(arg);
break;
case FLOAT:
if (arg->type == floattype)
arg = convert(arg, doubletype, 1);
break;
}
par = node(OPAR, arg->type, par, arg);
continue;
}
if (--n < 0) {
if (!toomany)
errorp("too many arguments in function call");
toomany = 1;
continue;
}
++targs;
if ((arg = convert(arg, argtype, 0)) != NULL) {
par = node(OPAR, arg->type, par, arg);
continue;
}
errorp("incompatible type for argument %d in function call",
tp->n.elem - n);
} while (accept(','));
no_pars:
expect(')');
if (n > 0 && *targs != ellipsistype)
errorp("too few arguments in function call");
op = (tp->prop&TELLIPSIS) ? OCALLE : OCALL;
return node(op, rettype, np, par);
}
static Node *unary(int);
static Type *
typeof(Node *np)
{
Type *tp;
if (np == NULL)
unexpected();
tp = np->type;
freetree(np);
return tp;
}
static Type *
sizeexp(void)
{
Type *tp;
expect('(');
switch (yytoken) {
case TYPE:
case TYPEIDEN:
tp = typename();
break;
default:
tp = typeof(unary(0));
break;
}
expect(')');
return tp;
}
static Node *
postfix(Node *lp)
{
int op;
Node *rp;
for (;;) {
switch (yytoken) {
case '[':
next();
rp = xexpr();
expect(']');
lp = array(decay(lp), rp);
break;
case DEC:
case INC:
op = (yytoken == INC) ? OINC : ODEC;
lp = incdec(decay(lp), op);
next();
break;
case INDIR:
lp = content(OPTR, decay(lp));
case '.':
lp = field(decay(lp));
break;
case '(':
lp = arguments(decay(lp));
lp->flags |= NEFFECT;
break;
default:
return lp;
}
}
}
static Node *cast(int);
static Node *
unary(int needdecay)
{
Node *(*fun)(int, Node *), *np;
int op;
Type *tp;
switch (yytoken) {
case '!': op = 0; fun = negation; break;
case '+': op = OADD; fun = numericaluop; break;
case '-': op = OSNEG; fun = numericaluop; break;
case '~': op = OCPL; fun = integeruop; break;
case '&': op = OADDR; fun = address; break;
case '*': op = OPTR; fun = content; break;
case SIZEOF:
next();
tp = (yytoken == '(') ? sizeexp() : typeof(unary(0));
if (!(tp->prop & TDEFINED))
errorp("sizeof applied to an incomplete type");
return sizeofnode(tp);
case INC:
case DEC:
op = (yytoken == INC) ? OA_ADD : OA_SUB;
next();
np = incdec(unary(1), op);
goto chk_decay;
case DEFINED:
return defined();
default:
np = postfix(primary());
goto chk_decay;
}
next();
np = (*fun)(op, cast(op != OADDR));
chk_decay:
if (needdecay)
np = decay(np);
return np;
}
static Node *
cast(int needdecay)
{
Node *tmp, *np;
Type *tp;
static int nested;
if (!accept('('))
return unary(needdecay);
switch (yytoken) {
case TQUALIFIER:
case TYPE:
case TYPEIDEN:
tp = typename();
expect(')');
if (yytoken == '{')
return initlist(tp);
switch (tp->op) {
case ARY:
error("cast specifies an array type");
default:
tmp = cast(needdecay);
if ((np = convert(tmp, tp, 1)) == NULL)
error("bad type conversion requested");
np->flags &= ~NLVAL;
}
break;
default:
if (nested == NR_SUBEXPR)
error("too many expressions nested by parentheses");
++nested;
np = xexpr();
--nested;
expect(')');
np = postfix(np);
break;
}
return np;
}
static Node *
mul(void)
{
Node *np, *(*fun)(int, Node *, Node *);
int op;
np = cast(1);
for (;;) {
switch (yytoken) {
case '*': op = OMUL; fun = arithmetic; break;
case '/': op = ODIV; fun = arithmetic; break;
case '%': op = OMOD; fun = integerop; break;
default: return np;
}
next();
np = (*fun)(op, np, cast(1));
}
}
static Node *
add(void)
{
int op;
Node *np;
np = mul();
for (;;) {
switch (yytoken) {
case '+': op = OADD; break;
case '-': op = OSUB; break;
default: return np;
}
next();
np = arithmetic(op, np, mul());
}
}
static Node *
shift(void)
{
int op;
Node *np;
np = add();
for (;;) {
switch (yytoken) {
case SHL: op = OSHL; break;
case SHR: op = OSHR; break;
default: return np;
}
next();
np = integerop(op, np, add());
}
}
static Node *
relational(void)
{
int op;
Node *np;
np = shift();
for (;;) {
switch (yytoken) {
case '<': op = OLT; break;
case '>': op = OGT; break;
case GE: op = OGE; break;
case LE: op = OLE; break;
default: return np;
}
next();
np = compare(op, np, shift());
}
}
static Node *
eq(void)
{
int op;
Node *np;
np = relational();
for (;;) {
switch (yytoken) {
case EQ: op = OEQ; break;
case NE: op = ONE; break;
default: return np;
}
next();
np = compare(op, np, relational());
}
}
static Node *
bit_and(void)
{
Node *np;
np = eq();
while (accept('&'))
np = integerop(OBAND, np, eq());
return np;
}
static Node *
bit_xor(void)
{
Node *np;
np = bit_and();
while (accept('^'))
np = integerop(OBXOR, np, bit_and());
return np;
}
static Node *
bit_or(void)
{
Node *np;
np = bit_xor();
while (accept('|'))
np = integerop(OBOR, np, bit_xor());
return np;
}
static Node *
and(void)
{
Node *np;
np = bit_or();
while (accept(AND))
np = logic(OAND, np, bit_or());
return np;
}
static Node *
or(void)
{
Node *np;
np = and();
while (accept(OR))
np = logic(OOR, np, and());
return np;
}
static Node *
ternary(void)
{
Node *cond;
cond = or();
while (accept('?')) {
Node *ifyes, *ifno, *np;
cond = exp2cond(cond, 0);
ifyes = xexpr();
expect(':');
ifno = ternary();
np = chkternary(ifyes, ifno);
cond = node(OASK, np->type, cond, np);
}
return cond;
}
static Node *
xassign(void)
{
Node *np, *(*fun)(int , Node *, Node *);
int op;
np = ternary();
for (;;) {
switch (yytoken) {
case '=': op = OASSIGN; fun = assignop; break;
case MUL_EQ: op = OA_MUL; fun = arithmetic; break;
case DIV_EQ: op = OA_DIV; fun = arithmetic; break;
case MOD_EQ: op = OA_MOD; fun = integerop; break;
case ADD_EQ: op = OA_ADD; fun = arithmetic; break;
case SUB_EQ: op = OA_SUB; fun = arithmetic; break;
case SHL_EQ: op = OA_SHL; fun = integerop; break;
case SHR_EQ: op = OA_SHR; fun = integerop; break;
case AND_EQ: op = OA_AND; fun = integerop; break;
case XOR_EQ: op = OA_XOR; fun = integerop; break;
case OR_EQ: op = OA_OR; fun = integerop; break;
default: return np;
}
chklvalue(np);
np->flags |= NEFFECT;
next();
np = (fun)(op, np, assign());
}
}
static Node *
xexpr(void)
{
Node *lp, *rp;
lp = xassign();
while (accept(',')) {
rp = xassign();
lp = node(OCOMMA, rp->type, lp, rp);
}
return lp;
}
Node *
assign(void)
{
return simplify(xassign());
}
Node *
constexpr(void)
{
Node *np;
np = ternary();
if (np && np->type->op == INT) {
np = simplify(convert(np, inttype, 0));
if (np->flags & NCONST)
return np;
}
freetree(np);
return NULL;
}
Node *
expr(void)
{
return simplify(xexpr());
}
Node *
condexpr(int neg)
{
Node *np;
np = exp2cond(xexpr(), neg);
if (np->flags & NCONST)
warn("conditional expression is constant");
return simplify(np);
}